/** * \file src/CaloProcessing.cpp * \author Emiliano Mocchiutti **/ // // C/C++ headers // #include #include // // ROOT headers // #include #include #include #include // // YODA headers // #include #include #include // // // #include // // this package headers // #include #include // // // Declaration of the core fortran routines // #define calol2cm calol2cm_ extern "C" int calol2cm(); #define calol2tr calol2tr_ extern "C" int calol2tr(); // using namespace std; // // // Public methods // CaloProcessing::~CaloProcessing(){ delete de; delete this; } CaloProcessing::CaloProcessing(){ // extern struct FlCaLevel1 clevel1_; extern struct FlCaLevel2 clevel2_; clevel1 = &clevel1_; clevel2 = &clevel2_; // trkseqno = 0; ClearStructs(); // memset(dexy, 0, 2*22*96*sizeof(Float_t)); memset(dexyc, 0, 2*22*96*sizeof(Float_t)); memset(mip, 0, 2*22*96*sizeof(Float_t)); memset(base, 0, 2*22*6*sizeof(Float_t)); memset(sbase, 0, 2*22*6*sizeof(Float_t)); calopar1 = true; calopar2 = true; calopar3 = true; ftcalopar1 = 0; ttcalopar1 = 0; ftcalopar2 = 0; ttcalopar2 = 0; ftcalopar3 = 0; ttcalopar3 = 0; } /** * Initialize CaloProcessing object **/ void CaloProcessing::ProcessingInit(TSQLServer *dbc, UInt_t hs, Int_t &sgnl, TTree *l0tree, Bool_t isdeb, Bool_t isverb){ // debug = isdeb; verbose = isverb; // l0tr=(TTree*)l0tree; de = new pamela::calorimeter::CalorimeterEvent(); l0calo = (TBranch*)l0tr->GetBranch("Calorimeter"); l0tr->SetBranchAddress("Calorimeter", &de); // trkseqno = 0; ClearStructs(); // GL_CALO_CALIB *glcalo = new GL_CALO_CALIB(); // sgnl = 0; UInt_t uptime = 0; // for (Int_t s = 0; s < 4; s++){ idcalib[s] = 0; fromtime[s] = 0; totime[s] = 0; calibno[s] = 0; ClearCalibVals(s); // sgnl = glcalo->Query_GL_CALO_CALIB(hs,uptime,s,dbc); if ( sgnl < 0 ){ if ( verbose ) printf(" CALORIMETER - ERROR: error from GLTables\n"); return; }; // idcalib[s] = glcalo->ID_ROOT_L0; fromtime[s] = glcalo->FROM_TIME; if ( glcalo->TO_TIME < hs ){ // calibration is corrupted and we are using the one that preceed the good one totime[s] = uptime; } else { totime[s] = glcalo->TO_TIME; }; calibno[s] = glcalo->EV_ROOT; // if ( totime[s] == 0 ){ if ( verbose ) printf(" CALORIMETER - WARNING: data with no associated calibration\n"); ClearCalibVals(s); sgnl = 100; }; }; // // determine path and name and entry of the calibration file // GL_ROOT *glroot = new GL_ROOT(); if ( verbose ) printf("\n"); for (Int_t s = 0; s < 4; s++){ if ( verbose ) printf(" ** SECTION %i **\n",s); if ( totime[s] > 0 ){ // sgnl = glroot->Query_GL_ROOT(idcalib[s],dbc); if ( sgnl < 0 ){ if ( verbose ) printf(" CALORIMETER - ERROR: error from GLTables\n"); return; }; // stringstream name; name.str(""); name << glroot->PATH.Data() << "/"; name << glroot->NAME.Data(); // fcalname[s] = (TString)name.str().c_str(); if ( verbose ) printf(" - runheader at time %u. From time %u to time %u \n use file %s \n calibration at entry %i \n\n",hs,fromtime[s],totime[s],fcalname[s].Data(),calibno[s]); } else { if ( verbose ) printf(" - runheader at time %u. NO CALIBRATION INCLUDE THE RUNHEADER! ",hs); }; sgnl = LoadCalib(s); if ( sgnl ) break; }; // delete glcalo; delete glroot; // return; // } Int_t CaloProcessing::ChkCalib(TSQLServer *dbc, UInt_t atime){ Int_t sgnl = 0; for ( Int_t s = 0; s < 4; s++){ if ( atime > totime[s] ){ sgnl = Update(dbc,atime,s); if ( sgnl < 0 ) return(sgnl); }; }; return(sgnl); } Int_t CaloProcessing::ChkParam(TSQLServer *dbc, UInt_t runheader){ stringstream calfile; stringstream bmfile; stringstream aligfile; Int_t error = 0; FILE *f = 0; ifstream badfile; GL_PARAM *glparam = new GL_PARAM(); // if ( calopar1 || ( ttcalopar1 != 0 && ttcalopar1 < runheader ) ){ calopar1 = false; // // determine where I can find calorimeter ADC to MIP conversion file // if ( verbose ) printf(" Querying DB for calorimeter parameters files...\n"); // error = 0; error = glparam->Query_GL_PARAM(runheader,101,dbc); if ( error < 0 ) return(error); // calfile.str(""); calfile << glparam->PATH.Data() << "/"; calfile << glparam->NAME.Data(); ftcalopar1 = glparam->FROM_TIME; ttcalopar1 = glparam->TO_TIME; // if ( verbose ) printf("\n Using ADC to MIP conversion file: \n %s \n",calfile.str().c_str()); f = fopen(calfile.str().c_str(),"rb"); if ( !f ){ if ( verbose ) printf(" CALORIMETER - ERROR: no ADC to MIP file!\n"); return(-105); }; // for (Int_t m = 0; m < 2 ; m++ ){ for (Int_t k = 0; k < 22; k++ ){ for (Int_t l = 0; l < 96; l++ ){ fread(&mip[m][k][l],sizeof(mip[m][k][l]),1,f); }; }; }; fclose(f); }; // if ( calopar2 || ( ttcalopar2 != 0 && ttcalopar2 < runheader ) ){ calopar2 = false; // // determine where I can find calorimeter alignment file // // error = 0; error = glparam->Query_GL_PARAM(runheader,102,dbc); if ( error < 0 ) return(error); // aligfile.str(""); aligfile << glparam->PATH.Data() << "/"; aligfile << glparam->NAME.Data(); ftcalopar2 = glparam->FROM_TIME; ttcalopar2 = glparam->TO_TIME; // if ( verbose ) printf("\n Using alignment file: \n %s \n",aligfile.str().c_str()); f = fopen(aligfile.str().c_str(),"rb"); if ( !f ){ if ( verbose ) printf(" CALORIMETER - ERROR: no alignement file!\n"); return(-106); }; // fread(&clevel1->xalig,sizeof(clevel1->xalig),1,f); if ( debug ) printf(" xalig = %f \n",clevel1->xalig); fread(&clevel1->yalig,sizeof(clevel1->yalig),1,f); if ( debug ) printf(" yalig = %f \n",clevel1->yalig); fread(&clevel1->zalig,sizeof(clevel1->zalig),1,f); if ( debug ) printf(" zalig = %f \n",clevel1->zalig); fread(&clevel1->emin,sizeof(clevel1->emin),1,f); if ( debug ) printf(" signal threshold = %f \n",clevel1->emin); // fclose(f); }; // // Load offline bad strip mask // if ( calopar3 || ( ttcalopar3 != 0 && ttcalopar3 < runheader ) ){ calopar3 = false; // // determine where I can find calorimeter alignment file // // error = 0; error = glparam->Query_GL_PARAM(runheader,103,dbc); if ( error < 0 ) return(error); // bmfile.str(""); bmfile << glparam->PATH.Data() << "/"; bmfile << glparam->NAME.Data(); ftcalopar3 = glparam->FROM_TIME; ttcalopar3 = glparam->TO_TIME; // if ( verbose ) printf("\n Using bad strip offline mask file: \n %s \n\n",bmfile.str().c_str()); badfile.open(bmfile.str().c_str()); if ( !badfile ){ if ( verbose ) printf(" CALORIMETER - ERROR: no bad strip offline mask file!\n"); return(-115); }; // Bool_t isdone = false; Int_t bad = 0; Int_t view = 1; Int_t strip = 0; Int_t plane = 21; while ( !isdone ) { badfile >> bad; obadmask[view][plane][strip] = bad; if ( debug && bad ) printf(" SETTING view %i plane %i strip %i BAD = %i \n",view,plane,strip,bad); strip++; if ( strip > 95 ){ strip = 0; plane--; if ( plane < 0 ){ plane = 21; view--; }; if ( view < 0 ) isdone = true; }; }; // badfile.close(); }; // delete glparam; // return(0); } void CaloProcessing::FindBaseRaw(Int_t l, Int_t m, Int_t pre){ Float_t minstrip = 100000.; Float_t rms = 0.; base[l][m][pre] = 0.; for (Int_t e = pre*16; e < (pre+1)*16 ; e++){ if ( calgood[l][m][e] == 0. && obadmask[l][m][e] == 0 && dexy[l][m][e]-calped[l][m][e] < minstrip && dexy[l][m][e] > 0.) { minstrip = dexy[l][m][e]-calped[l][m][e]; rms = calthr[l][m][pre]; }; }; if ( minstrip != 100000. ) { Float_t strip6s = 0.; for (Int_t e = pre*16; e < (pre+1)*16 ; e++){ if ( (dexy[l][m][e]-calped[l][m][e]) >= minstrip && (dexy[l][m][e]-calped[l][m][e]) <= (minstrip+rms) ) { strip6s += 1.; base[l][m][pre] += (dexy[l][m][e] - calped[l][m][e]); }; // // compression // if ( abs((int)(dexy[l][m][e]-calped[l][m][e])) <= (minstrip+rms) ) { dexyc[l][m][e] = 0.; } else { dexyc[l][m][e] = dexy[l][m][e]; }; }; if ( strip6s >= 9. ){ Double_t arro = base[l][m][pre]/strip6s; Float_t deci = 1000.*((float)arro - float(int(arro))); if ( deci < 500. ) { arro = double(int(arro)); } else { arro = 1. + double(int(arro)); }; base[l][m][pre] = arro; } else { base[l][m][pre] = 31000.; for (Int_t e = pre*16; e < (pre+1)*16 ; e++){ dexyc[l][m][e] = dexy[l][m][e]; }; }; } else { base[l][m][pre] = 31000.; }; } Int_t CaloProcessing::Calibrate(Int_t ei){ // // get entry ei // l0calo->GetEntry(ei); // // if it was not a selftrigger event, could it ever been a selftrigger event? if so trigty = 3. // Int_t val = 0; Int_t del = 1100; if ( clevel2->trigty != 2. ){ for (Int_t sec = 0; sec < 4; sec++){ val = (Int_t)de->calselftrig[sec][6]; del = delay(val); if ( del < 1100 ){ clevel2->trigty = 3.; break; }; }; }; // Int_t se = 5; Int_t done = 0; Int_t pre = -1; Bool_t isCOMP = false; Bool_t isFULL = false; Bool_t isRAW = false; Float_t ener; Int_t doneb = 0; Int_t donec = 0; Int_t ck = 0; Int_t ipre = 0; Int_t ip[3] = {0}; Float_t base0, base1, base2; base0 = 0.; base1 = 0.; base2 = 0.; Float_t qpre[6] = {0.,0.,0.,0.,0.,0.}; Float_t ene[96]; Int_t chdone[4] = {0,0,0,0}; Int_t pe = 0; // Float_t ener0 = 0.; Float_t cbase0 = 0.; Bool_t pproblem = false; // Float_t tim = 0.; Int_t plo = 0; Int_t fbi = 0; Int_t cle = 0; // // run over views and planes // for (Int_t l = 0; l < 2; l++){ for (Int_t m = 0; m < 22; m++){ // // determine the section number // se = 5; if (l == 0 && m%2 == 0) se = 3; if (l == 0 && m%2 != 0) se = 2; if (l == 1 && m%2 == 0) se = 1; if (l == 1 && m%2 != 0) se = 0; // // determine what kind of event we are going to analyze // isCOMP = false; isFULL = false; isRAW = false; if ( de->stwerr[se] & (1 << 16) ) isCOMP = true; if ( de->stwerr[se] & (1 << 17) ) isFULL = true; if ( de->stwerr[se] & (1 << 3) ) isRAW = true; if ( !chdone[se] ){ // // check for any error in the event // clevel2->crc[se] = 0; if ( de->perror[se] == 132 ){ clevel2->crc[se] = 1; pe++; }; clevel2->perr[se] = 0; if ( de->perror[se] != 0 ){ clevel2->perr[se] = 1; pe++; }; clevel2->swerr[se] = 0; for (Int_t j = 0; j < 7 ; j++){ if ( (j != 3) && (de->stwerr[se] & (1 << j)) ){ clevel2->swerr[se] = 1; pe++; }; }; chdone[se] = 1; }; if ( clevel2->crc[se] == 0 && (clevel1->good2 == 1 || clevel2->trigty >= 2) ){ pre = -1; // for (Int_t nn = 0; nn < 96; nn++){ ene[nn] = 0.; dexy[l][m][nn] = de->dexy[l][m][nn] ; dexyc[l][m][nn] = de->dexyc[l][m][nn] ; }; // // run over preamplifiers // pre = -1; cbase0 = 0.; for (Int_t i = 0; i < 3; i++){ for (Int_t j = 0; j < 2; j++){ pre = j + i*2; // // baseline check and calculation // if ( !isRAW ) { base[l][m][pre] = de->base[l][m][pre] ; cbase0 += base[l][m][pre]; } else { // // if it is a raw event and we haven't checked // yet, calculate the baseline. // FindBaseRaw(l,m,pre); cbase0 += base[l][m][pre]; }; }; }; // // run over strips // pre = -1; ener0 = 0.; for (Int_t i = 0 ; i < 3 ; i++){ ip[i] = 0; for (Int_t n = i*32 ; n < (i+1)*32 ; n++){ if (n%16 == 0) { ck = 0; done = 0; doneb = 0; donec = 0; pre++; qpre[pre] = 0.; }; // // baseline check and calculation // // no suitable new baseline, use old ones! // if ( !done ){ if ( (base[l][m][pre] == 31000. || base[l][m][pre] == 0.) ){ ck = 1; if (pre%2 == 0) { ip[i] = pre + 1; } else { ip[i] = pre - 1; }; if ( (base[l][m][ip[i]] == 31000. || base[l][m][ip[i]] == 0.) ){ // ck = 2; if ( sbase[l][m][pre] == 31000. || sbase[l][m][pre] == 0. ) { ck = 3; }; }; done = 1; }; }; // // CALIBRATION ALGORITHM // if ( !doneb ){ switch (ck) { case 0: base0 = base[l][m][pre]; base2 = calbase[l][m][pre]; break; case 1: base0 = base[l][m][ip[i]]; base2 = calbase[l][m][ip[i]]; break; case 2: base0 = sbase[l][m][pre]; base2 = calbase[l][m][pre]; break; case 3: base0 = calbase[l][m][pre]; base2 = calbase[l][m][pre]; break; }; base1 = calbase[l][m][pre]; doneb = 1; }; ener = dexyc[l][m][n]; ener0 += ener; clevel1->estrip[n][m][l] = 0.; if ( base0>0 && base0 < 30000. ){ if ( !donec && (base0 - base1 + base2) != 0. ){ sbase[l][m][pre] = base0 - base1 + base2; donec = 1; }; if ( ener > 0. ){ clevel1->estrip[n][m][l] = (ener - calped[l][m][n] - base0 - base1 + base2)/mip[l][m][n] ; // // OK, now in estrip we have the energy deposit in MIP of all the strips for this event (at the end of loops of course) // qpre[pre] += clevel1->estrip[n][m][l]; }; }; }; if (ck == 1){ if (ip[i]%2 == 0) { ipre = ip[i] + 1; } else { ipre = ip[i] - 1; }; for (Int_t j = ipre*16 ; j < (ipre+1)*16 ; j++){ clevel1->estrip[j][m][l] += (qpre[ipre] - qpre[ip[i]]) * 0.00478; }; }; if (ck == 2){ for (Int_t j = i*32 ; j < (i+1)*32 ; j++){ ipre = j/16 + 1; clevel1->estrip[j][m][l] += qpre[ipre] * 0.00478; }; }; }; // if ( ener0 == 0. && cbase0 == 0. && !pproblem ){ if ( verbose ) printf(" Calorimeter power problems! event marked as bad \n"); pproblem = true; pe++; }; // Int_t j4 = -4; Int_t jjj = -3; Int_t jj = -2; for (Int_t j = 0 ; j < 100 ; j++){ jj++; jjj++; j4++; if ( j < 96 ) ene[j] = clevel1->estrip[j][m][l]; if ( jj >= 0 && jj < 96 ){ if ( jj != 0 && jj != 32 && jj != 64 ) ene[jj-1] += -clevel1->estrip[jj][m][l] * 0.01581; if ( jj != 31 && jj != 63 && jj != 95 ) ene[jj+1] += -clevel1->estrip[jj][m][l] * 0.01581; }; if ( jjj >= 0 && jjj < 96 ){ if ( jjj != 0 && jjj != 32 && jjj != 64 ) clevel1->estrip[jjj-1][m][l] += -ene[jjj] * 0.01581; if ( jjj != 31 && jjj != 63 && jjj != 95 ) clevel1->estrip[jjj+1][m][l] += -ene[jjj] * 0.01581; }; if ( j4 >= 0 && j4 < 96 ){ // // NOTICE: THE FOLLOWING LINE EXCLUDE ALL STRIPS FOR WHICH THE RMS*4 IS GREATER THAN 26 !!! <=============== IMPORTANT! =================> // if ( obadmask[l][m][j4] == 1 || clevel1->estrip[j4][m][l] <= clevel1->emin || calrms[l][m][j4] > 26 ){ clevel1->estrip[j4][m][l] = 0.; }; // // code and save the energy for each strip in svstrip // if ( clevel1->estrip[j4][m][l] > clevel1->emin ){ // tim = 100000.; plo = m; fbi = 0; if ( clevel1->estrip[j4][m][l] > 1. ){ tim = 10000.; plo = m; fbi = 1; }; if ( clevel1->estrip[j4][m][l] > 10. ){ tim = 1000.; plo = 22 + m; fbi = 1; }; if ( clevel1->estrip[j4][m][l] > 100. ){ tim = 100.; plo = 22 + m; fbi = 0; }; if ( clevel1->estrip[j4][m][l] > 1000. ){ tim = 10.; plo = 44 + m; fbi = 0; }; if ( clevel1->estrip[j4][m][l] > 10000. ){ tim = 1.; plo = 66 + m; fbi = 0; }; // cle = (Int_t)lroundf(tim*clevel1->estrip[j4][m][l]); // if ( l == 0 ){ // // +-PPSSmmmm.mmmm // svstrip[istrip] = fbi*1000000000 + plo*10000000 + j4*100000 + cle; } else { svstrip[istrip] = -(fbi*1000000000 + plo*10000000 + j4*100000 + cle); }; // if ( ei == 770 ) printf(" j %i l %i m %i estrip %f \n",j4,l,m,clevel1->estrip[j4][m][l]); // if ( ei == 770 ) printf(" num lim %i fbi %i tim %f plo %i cle %i \n",numeric_limits::max(),fbi,tim,plo,cle); // if ( ei == 770 ) printf(" svstrip %i \n",svstrip[istrip]); // istrip++; }; }; }; // } else { for (Int_t nn = 0; nn < 96; nn++){ clevel1->estrip[nn][m][l] = 0.; }; }; }; }; if ( !pe ){ clevel2->good = 1; } else { clevel2->good = 0; }; return(0); } void CaloProcessing::GetTrkVar(){ calol2tr(); } void CaloProcessing::FillTrkVar(CaloLevel2 *ca, Int_t nutrk){ // CaloTrkVar *t_ca = new CaloTrkVar(); // t_ca->trkseqno = trkseqno; t_ca->ncore = (Int_t)clevel2->ncore; t_ca->qcore = clevel2->qcore; t_ca->noint = (Int_t)clevel2->noint; t_ca->ncyl = (Int_t)clevel2->ncyl; t_ca->qcyl = clevel2->qcyl; t_ca->qtrack = clevel2->qtrack; t_ca->qtrackx = clevel2->qtrackx; t_ca->qtracky = clevel2->qtracky; t_ca->dxtrack = clevel2->dxtrack; t_ca->dytrack = clevel2->dytrack; t_ca->qlast = clevel2->qlast; t_ca->nlast = (Int_t)clevel2->nlast; t_ca->qpre = clevel2->qpre; t_ca->npre = (Int_t)clevel2->npre; t_ca->qpresh = clevel2->qpresh; t_ca->npresh = (Int_t)clevel2->npresh; t_ca->qtr = clevel2->qtr; t_ca->ntr = (Int_t)clevel2->ntr; t_ca->planetot = (Int_t)clevel2->planetot; t_ca->qmean = clevel2->qmean; t_ca->dX0l = clevel2->dX0l; t_ca->qlow = clevel2->qlow; t_ca->nlow = (Int_t)clevel2->nlow; // memcpy(t_ca->tibar,clevel2->tibar,sizeof(clevel2->tibar)); memcpy(t_ca->tbar,clevel2->tbar,sizeof(clevel2->tbar)); // if ( trkseqno == -1 ){ ca->impx = clevel2->impx; ca->impy = clevel2->impy; ca->tanx = clevel2->tanx; ca->tany = clevel2->tany; ca->elen = clevel2->elen; ca->selen = clevel2->selen; memcpy(ca->cibar,clevel2->cibar,sizeof(clevel2->cibar)); memcpy(ca->cbar,clevel2->cbar,sizeof(clevel2->cbar)); memcpy(ca->planemax,clevel2->planemax,sizeof(clevel2->planemax)); memcpy(ca->varcfit,clevel2->varcfit,sizeof(clevel2->varcfit)); memcpy(ca->npcfit,clevel2->npcfit,sizeof(clevel2->npcfit)); }; // TClonesArray &t = *ca->CaloTrk; new(t[nutrk]) CaloTrkVar(*t_ca); // delete t_ca; // ClearTrkVar(); } void CaloProcessing::GetCommonVar(){ calol2cm(); } void CaloProcessing::FillCommonVar(CaloLevel2 *ca){ // ca->good = clevel2->good; if ( clevel2->trigty == 2. ){ ca->selftrigger = 1; } else { ca->selftrigger = 0; }; memcpy(ca->perr,clevel2->perr,sizeof(clevel2->perr)); memcpy(ca->swerr,clevel2->swerr,sizeof(clevel2->swerr)); memcpy(ca->crc,clevel2->crc,sizeof(clevel2->crc)); ca->nstrip = (Int_t)clevel2->nstrip; ca->qtot = clevel2->qtot; ca->impx = clevel2->impx; ca->impy = clevel2->impy; ca->tanx = clevel2->tanx; ca->tany = clevel2->tany; ca->nx22 = (Int_t)clevel2->nx22; ca->qx22 = clevel2->qx22; ca->qmax = clevel2->qmax; ca->elen = clevel2->elen; ca->selen = clevel2->selen; ca->estrip = TArrayI(ca->nstrip,svstrip); memcpy(ca->qq,clevel2->qq,sizeof(clevel2->qq)); memcpy(ca->planemax,clevel2->planemax,sizeof(clevel2->planemax)); memcpy(ca->varcfit,clevel2->varcfit,sizeof(clevel2->varcfit)); memcpy(ca->npcfit,clevel2->npcfit,sizeof(clevel2->npcfit)); memcpy(ca->cibar,clevel2->cibar,sizeof(clevel2->cibar)); memcpy(ca->cbar,clevel2->cbar,sizeof(clevel2->cbar)); // } void CaloProcessing::ClearStructs(){ ClearTrkVar(); ClearCommonVar(); } void CaloProcessing::RunClose(){ l0tr->Delete(); ClearStructs(); // memset(dexy, 0, 2*22*96*sizeof(Float_t)); memset(dexyc, 0, 2*22*96*sizeof(Float_t)); memset(base, 0, 2*22*6*sizeof(Float_t)); memset(sbase, 0, 2*22*6*sizeof(Float_t)); // } // // Private methods // void CaloProcessing::ClearTrkVar(){ clevel2->ncore = 0; clevel2->qcore = 0.; clevel2->noint = 0.; clevel2->ncyl = 0.; clevel2->qcyl = 0.; clevel2->qtrack = 0.; clevel2->qtrackx = 0.; clevel2->qtracky = 0.; clevel2->dxtrack = 0.; clevel2->dytrack = 0.; clevel2->qlast = 0.; clevel2->nlast = 0.; clevel2->qpre = 0.; clevel2->npre = 0.; clevel2->qpresh = 0.; clevel2->npresh = 0.; clevel2->qlow = 0.; clevel2->nlow = 0.; clevel2->qtr = 0.; clevel2->ntr = 0.; clevel2->planetot = 0.; clevel2->qmean = 0.; clevel2->dX0l = 0.; clevel2->elen = 0.; clevel2->selen = 0.; memset(clevel1->al_p, 0, 5*2*sizeof(Double_t)); memset(clevel2->tibar, 0, 2*22*sizeof(Int_t)); memset(clevel2->tbar, 0, 2*22*sizeof(Float_t)); } void CaloProcessing::ClearCommonVar(){ istrip = 0; clevel2->trigty = -1.; clevel2->good = 0; clevel2->nstrip = 0.; clevel2->qtot = 0.; clevel2->impx = 0.; clevel2->impy = 0.; clevel2->tanx = 0.; clevel2->tany = 0.; clevel2->qmax = 0.; clevel2->nx22 = 0.; clevel2->qx22 = 0.; memset(clevel2->perr, 0, 4*sizeof(Int_t)); memset(clevel2->swerr, 0, 4*sizeof(Int_t)); memset(clevel2->crc, 0, 4*sizeof(Int_t)); memset(clevel2->qq, 0, 4*sizeof(Int_t)); memset(clevel2->varcfit, 0, 2*sizeof(Float_t)); memset(clevel2->npcfit, 0, 2*sizeof(Int_t)); memset(clevel2->planemax, 0, 2*sizeof(Int_t)); memset(clevel2->cibar, 0, 2*22*sizeof(Int_t)); memset(clevel2->cbar, 0, 2*22*sizeof(Float_t)); } void CaloProcessing::ClearCalibVals(Int_t s){ // for ( Int_t d=0 ; d<11 ;d++ ){ Int_t pre = -1; for ( Int_t j=0; j<96 ;j++){ if ( j%16 == 0 ) pre++; if ( s == 2 ){ calped[0][2*d+1][j] = 0.; cstwerr[3] = 0.; cperror[3] = 0.; calgood[0][2*d+1][j] = 0.; calthr[0][2*d+1][pre] = 0.; calrms[0][2*d+1][j] = 0.; calbase[0][2*d+1][pre] = 0.; calvar[0][2*d+1][pre] = 0.; }; if ( s == 3 ){ calped[0][2*d][j] = 0.; cstwerr[1] = 0.; cperror[1] = 0.; calgood[0][2*d][j] = 0.; calthr[0][2*d][pre] = 0.; calrms[0][2*d][j] = 0.; calbase[0][2*d][pre] = 0.; calvar[0][2*d][pre] = 0.; }; if ( s == 0 ){ calped[1][2*d][j] = 0.; cstwerr[0] = 0.; cperror[0] = 0.; calgood[1][2*d][j] = 0.; calthr[1][2*d][pre] = 0.; calrms[1][2*d][j] = 0.; calbase[1][2*d][pre] = 0.; calvar[1][2*d][pre] = 0.; }; if ( s == 1 ){ calped[1][2*d+1][j] = 0.; cstwerr[2] = 0.; cperror[2] = 0.; calgood[1][2*d+1][j] = 0.; calthr[1][2*d+1][pre] = 0.; calrms[1][2*d+1][j] = 0.; calbase[1][2*d+1][pre] = 0.; calvar[1][2*d+1][pre] = 0.; }; }; }; return; } Int_t CaloProcessing::Update(TSQLServer *dbc, UInt_t atime, Int_t s){ // Int_t sgnl = 0; // GL_CALO_CALIB *glcalo = new GL_CALO_CALIB(); // sgnl = 0; // idcalib[s] = 0; fromtime[s] = 0; totime[s] = 0; calibno[s] = 0; ClearCalibVals(s); // UInt_t uptime = 0; // sgnl = glcalo->Query_GL_CALO_CALIB(atime,uptime,s,dbc); if ( sgnl < 0 ){ if ( verbose ) printf(" CALORIMETER - ERROR: error from GLTables\n"); return(sgnl); }; // idcalib[s] = glcalo->ID_ROOT_L0; fromtime[s] = glcalo->FROM_TIME; if ( glcalo->TO_TIME < atime ){ // calibration is corrupted and we are using the one that preceed the good one totime[s] = uptime; } else { totime[s] = glcalo->TO_TIME; }; // totime[s] = glcalo->TO_TIME; calibno[s] = glcalo->EV_ROOT; // if ( totime[s] == 0 ){ if ( verbose ) printf(" CALORIMETER - WARNING: data with no associated calibration\n"); ClearCalibVals(s); sgnl = 100; }; // // determine path and name and entry of the calibration file // GL_ROOT *glroot = new GL_ROOT(); if ( verbose ) printf("\n"); if ( verbose ) printf(" ** SECTION %i **\n",s); // sgnl = glroot->Query_GL_ROOT(idcalib[s],dbc); if ( sgnl < 0 ){ if ( verbose ) printf(" CALORIMETER - ERROR: error from GLTables\n"); return(sgnl); }; // stringstream name; name.str(""); name << glroot->PATH.Data() << "/"; name << glroot->NAME.Data(); // fcalname[s] = (TString)name.str().c_str(); if ( verbose ) printf(" - event at time %u. From time %u to time %u \n use file %s \n calibration at entry %i \n\n",atime,fromtime[s],totime[s],fcalname[s].Data(),calibno[s]); // sgnl = LoadCalib(s); // if ( sgnl != 0 ) return(sgnl); delete glcalo; delete glroot; // return(0); // } Int_t CaloProcessing::LoadCalib(Int_t s){ // ifstream myfile; myfile.open(fcalname[s].Data()); if ( !myfile ){ return(-107); }; myfile.close(); // TFile *File = new TFile(fcalname[s].Data()); if ( !File ) return(-108); TTree *tr = (TTree*)File->Get("CalibCalPed"); if ( !tr ) return(-109); // TBranch *calo = tr->GetBranch("CalibCalPed"); // pamela::CalibCalPedEvent *ce = 0; tr->SetBranchAddress("CalibCalPed", &ce); // Long64_t ncalibs = calo->GetEntries(); // if ( !ncalibs ) return(-110); // calo->GetEntry(calibno[s]); // if (ce->cstwerr[s] != 0 && ce->cperror[s] == 0 ) { for ( Int_t d=0 ; d<11 ;d++ ){ Int_t pre = -1; for ( Int_t j=0; j<96 ;j++){ if ( j%16 == 0 ) pre++; if ( s == 2 ){ calped[0][2*d+1][j] = ce->calped[3][d][j]; cstwerr[3] = ce->cstwerr[3]; cperror[3] = ce->cperror[3]; calgood[0][2*d+1][j] = ce->calgood[3][d][j]; calthr[0][2*d+1][pre] = ce->calthr[3][d][pre]; calrms[0][2*d+1][j] = ce->calrms[3][d][j]; calbase[0][2*d+1][pre] = ce->calbase[3][d][pre]; calvar[0][2*d+1][pre] = ce->calvar[3][d][pre]; }; if ( s == 3 ){ calped[0][2*d][j] = ce->calped[1][d][j]; cstwerr[1] = ce->cstwerr[1]; cperror[1] = ce->cperror[1]; calgood[0][2*d][j] = ce->calgood[1][d][j]; calthr[0][2*d][pre] = ce->calthr[1][d][pre]; calrms[0][2*d][j] = ce->calrms[1][d][j]; calbase[0][2*d][pre] = ce->calbase[1][d][pre]; calvar[0][2*d][pre] = ce->calvar[1][d][pre]; }; if ( s == 0 ){ calped[1][2*d][j] = ce->calped[0][d][j]; cstwerr[0] = ce->cstwerr[0]; cperror[0] = ce->cperror[0]; calgood[1][2*d][j] = ce->calgood[0][d][j]; calthr[1][2*d][pre] = ce->calthr[0][d][pre]; calrms[1][2*d][j] = ce->calrms[0][d][j]; calbase[1][2*d][pre] = ce->calbase[0][d][pre]; calvar[1][2*d][pre] = ce->calvar[0][d][pre]; }; if ( s == 1 ){ calped[1][2*d+1][j] = ce->calped[2][d][j]; cstwerr[2] = ce->cstwerr[2]; cperror[2] = ce->cperror[2]; calgood[1][2*d+1][j] = ce->calgood[2][d][j]; calthr[1][2*d+1][pre] = ce->calthr[2][d][pre]; calrms[1][2*d+1][j] = ce->calrms[2][d][j]; calbase[1][2*d+1][pre] = ce->calbase[2][d][pre]; calvar[1][2*d+1][pre] = ce->calvar[2][d][pre]; }; }; }; } else { if ( verbose ) printf(" CALORIMETER - ERROR: problems finding a good calibration in this file! \n\n "); return(-111); }; File->Close(); return(0); }